Download SURGICAL EXCISION OF MYCOTIC (CLADOSPORIUM SP

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts
no text concepts found
Transcript
Journal of Zoo and Wildlife Medicine 37(4): 524–530, 2006
Copyright 2006 by American Association of Zoo Veterinarians
SURGICAL EXCISION OF MYCOTIC (CLADOSPORIUM SP.)
GRANULOMAS FROM THE MANTLE OF A CUTTLEFISH
(SEPIA OFFICINALIS)
Craig A. Harms, D.V.M., Ph.D., Dipl. A.C.Z.M., Gregory A. Lewbart, M.S., V.M.D., Dipl.
A.C.Z.M., Ryan McAlarney, Larry S. Christian, Kyleigh Geissler, D.V.M., and Carol Lemons
Abstract: An adult female European cuttlefish (Sepia officinalis) from a public aquarium presented with an eruptive
skin lesion of the dorsal mantle. Radiographs, hemolymph collection, and excisional biopsy were performed using
anesthesia with ethanol 1.5–3% in seawater. Elastic and freely mobile skin permitted closure with minimal tension
following wide excision around the lesions, which did not appear to penetrate deep to the underlying cuttlebone. Biopsy
revealed hemocyte granulomas surrounding thin, septate, infrequently branching fungal hyphae, and culture yielded
Cladosporium sp. Itraconazole was administered postoperatively in food items. The cuttlefish recovered to normal
feeding and activity levels with complete surgical site healing. Two months following the procedure, the animal was
found dead in exhibit. Histopathologic examination revealed multisystemic fungal infection.
Key words: Cladosporium, cuttlefish, Sepia officinalis, surgery.
INTRODUCTION
Cuttlefish are popular animals in public and private aquarium displays and have been used as laboratory and food animals. Like other cephalopod
mollusks, such as octopus and squid, cuttlefish are
characterized by a highly developed neurological
system and complex behaviors, contrasted with a
relatively brief lifespan and death typically following shortly after reproduction.1 Disease, husbandry,
and therapeutics of cephalopods have received attention in recent years.3,4,6,11–13,15,17,18,20 The internal
shell of cuttlefish, the ‘‘cuttlebone,’’ can sustain
fractures and infections which can prove fatal.17,18
Fungal diseases of cephalopods are not commonly
reported, but include Fusarium sp. in chambered
nautilus (Nautilus pompilius) and Cladosporium sp.
in an unspecified octopus species.17 This report describes anesthesia and surgical treatment of a EuFrom the North Carolina State University, College of
Veterinary Medicine, Department of Clinical Sciences,
Center for Marine Sciences and Technology, 303 College
Circle, Morehead City, North Carolina 28557, USA
(Harms); North Carolina State University, College of Veterinary Medicine, Department of Clinical Sciences, 4700
Hillsborough St., Raleigh, North Carolina 27606, USA
(Lewbart, Christian); North Carolina Aquarium at Fort
Fisher, 900 Loggerhead Road, Kure Beach, North Carolina 28449, USA (McAlarney); North Carolina State University, College of Veterinary Medicine, Department of
Population Health and Pathobiology, 4700 Hillsborough
St., Raleigh, North Carolina 27606, USA (Geissler); and
North Carolina State University, Clinical Microbiology,
Veterinary Teaching Hospital, 4700 Hillsborough St., Raleigh, North Carolina 27606, USA (Lemons). Correspondence should be directed to Dr. Harms.
ropean cuttlefish (Sepia officinalis) with mycotic
dermatitis of the dorsal mantle caused by Cladosporium sp. infection.
CASE REPORT
An adult female captive cuttlefish (220 g) with a
history of an acute eruptive skin lesion of the dorsal
mantle was presented for examination. The lesion
began as a thickening and darkening of the skin,
and progressed to partial ulceration. The cuttlefish
had been obtained 5 mo previously at an estimated
age of 4–6 mo along with 11 others, 8 of which
remained and appeared healthy. Cuttlefish were
kept in a 3,400-L artificial seawater tank (waterquality ranges throughout holding: pH 7.8–8.1, salinity 33–35 psu (ppt), ammonia 0.01–0.18 mg/L,
nitrite 0.07–0.12 mg/L, nitrate 0–176 mg/L, temperature 21–23⬚C). Feeding and activity levels were
unchanged from prior to development of the skin
lesions. The week prior to presentation, a swab of
the ulcer for culture and sensitivity and a cytology
smear had been submitted to an outside laboratory
(Antech Diagnostics, Southaven, Mississippi
38671, USA). Culture yielded moderate growth of
an alpha hemolytic Streptococcus sp. sensitive to
all antibiotics tested. Cytology showed a highly cellular hemocytic response surrounding fungal hyphae that were grey, septate, and branching, with
blunt ends, and measuring approximately 4 ␮m
wide. Prior to receiving cytology results, treatment
with enrofloxacin (Baytril, 22.7 mg/ml, Bayer Corporation, Animal Health, Shawnee Mission, Kansas
66216, USA) 10 mg/kg p.o. q 12 h in food items4
was attempted, but resulted in feed refusal.
At the time of presentation, the original lesion
524
HARMS ET AL.—CUTTLEFISH SURGERY
525
Figure 1. Cuttlefish on recirculating anesthesia machine during surgery, showing double-tube delivery of ethanolcontaining seawater bilaterally to both ctenidia (gills), and mobility of skin for simple excision of the smaller skin
nodule.
had an open ulcer approximately 1.5 cm diameter
with underlying muscle exposed and a necrotic
core, but no cuttlebone exposure. It was located
dorsally on the left side of the mantle near the apex.
Craniomedial to and confluent with the original lesion was an irregular dark firm thickened area. The
combined lesions measured approximately 2.5 ⫻
3.0 cm. One isolated firm subcutaneous nodule was
present further cranially, just left of midline near
the middle of the mantle, measuring approximately
4 mm diameter. All lesions were freely mobile and
not attached to the underlying mantle musculature.
The cuttlefish was anesthetized for radiographs,
hemolymph collection, and excisional biopsy, using
ethanol 30 ml/L (3%) in seawater.14 Induction was
rapid, within 1 min, at which point the ethanol concentration was reduced to 15 ml/L (1.5%) by adding anesthesia-free seawater. A dorsoventral radiograph was obtained by removing the cuttlefish from
the anesthesia water, placing it directly on a film
cassette for image acquisition (52 kvp, 1.0 mAs,
Kodak X-Omatic cassette with Kodak Lanex medium screens and Kodak TMat G film, Rochester,
New York 14652, USA), and returning it to the
anesthesia water within 1 min. For maintenance and
the remaining diagnostics, the cuttlefish was transferred to a recirculating anesthesia system on a
smooth nonabrasive acrylic surgical platform9 with
two independent tubes delivering anesthesia water
bilaterally into the mantle cavity over both ctenidia
(gills) (Fig. 1). Respirations continued sporadically
throughout the procedure, but the cuttlefish remained unresponsive to tactile and surgical stimuli.
Hemolymph (0.5 ml) was collected from the muscular portion of the cephalic vein just dorsal to the
funnel with the use of a 1-ml syringe with 25-ga
9-mm needle for hemocyte count (manual count
with hemacytometer and no staining), hemocyte cytology (Wright-Giemsa stained hemolymph smear)
and hemolymph chemistry panel (Roche/Hitachi
912 Clinical Chemistry System, Roche Diagnostics,
Indianapolis, Indiana 46256, USA).
Enrofloxacin (10 mg/kg i.v.) was administered in
the cephalic vein preoperatively.4 Surgical scrub of
the biopsy sites was not performed to prevent skin
damage or toxic effects with recirculation of con-
526
JOURNAL OF ZOO AND WILDLIFE MEDICINE
Figure 2. Skin defect following excision of larger caudal granuloma, revealing the underlying white mantle tissue
(muscle). The smaller cranial granuloma site has been closed.
taminated anesthesia water. The smaller isolated
nodule was removed first, by lifting it by forceps
and sharply cutting the stretched skin below the
nodule with scissors (Fig. 1). The 5-mm-diameter
skin defect was closed with 4-0 polyglyconate on
a taper needle (Maxon威, 4-0 CV-23 taper, United
States Surgical, Norwalk, Connecticut 06850,
USA) in a simple continuous pattern. Because the
mobility and elasticity of the skin permitted a simple closure with little tension, the same excision
procedure was repeated on the larger lesion, resulting in a 3 ⫻ 4-cm oval skin defect (Fig. 2). The
underlying cuttlebone was palpable with instruments, but was completely covered by soft tissue
of the mantle. Skin closure with an interrupted cruciate pattern over the larger defect also closed readily, with little tension and no tendency to tear (Fig.
3). A single simple horizontal mattress suture was
placed initially, but this caused an eversion of the
skin, which was corrected by oversewing with a
single simple interrupted suture. The larger nodular
lesion adjacent to the ulcer was incised and
swabbed for bacterial and fungal culture. All excised tissue was preserved in 10% neutral buffered
formalin for routine histologic processing and staining with hematoxylin and eosin.
Total anesthesia time was 44 min. The cuttlefish
was transferred to anesthesia-free seawater for recovery, and respirations were assisted with gentle
whole mantle massage. Normal coordinated respirations returned within 2 min. The tentacles (the
paired protrusile appendages, versus the eight fixed
arms) remained extended and flaccid for 10 min
before they were retracted in response to light
pinching. Full recovery was achieved after 20 min
in anesthesia-free water.
Soft-tissue detail was poor on the radiograph, but
no radiolucent lytic or irregular areas of the cuttlebone were visualized. Radiographic findings plus
observations during lesion excision suggested that
the cuttlebone was not affected, which improved
the prognosis. Results of hemolymph analysis (Table 1) included hemocytes identified as monocytelike cells with large eosinophilic granules and
monomorphic nuclei. Concentrations of some analytes were beyond instrument linearity (sodium,
chloride, magnesium), and sample quantity was insufficient to perform dilutions to obtain an accurate
result. Sodium, chloride and magnesium hemolymph concentrations are reported in S. officinalis
to be 93%, 105% and 98% of concentrations found
in seawater, which are approximately 470, 548, and
54 mmol/L, respectively.16 Certain other analytes
registered below instrument range (urea nitrogen,
creatinine, albumin, gamma-glutamyl transferase,
and creatine kinase). Clinical pathology interpretation is hampered by a lack of published reference
ranges, and some assays included in the chemistry
HARMS ET AL.—CUTTLEFISH SURGERY
527
Figure 3. Dorsolateral view of cuttlefish following skin closure. One anesthesia-water delivery tube has been
removed for an unobstructed photograph. Notice the color change compared with Fig. 2.
panel have uncertain validity or relevance for an
invertebrate.
Bacterial culture yielded heavy growth of Vibrio
vulnificus, resistant to amoxicillin, ampicillin, cefazolin, cefoxitin, cephalothin, clindamycin, oxacillin, ticarcillin, and vancomycin, and sensitive to
amikacin, cefotaxime, chloramphenicol, ciprofloxacin, erythromycin, gentamicin, imipenem, nitrofurantoin, piperacillin, tetracycline, tobramycin,
and trimethoprim-sulfa. Fungal culture yielded
heavy growth of Cladosporium sp. Histopathology
revealed marked expansion and replacement of the
subcutis by multifocal to coalescing granulomas
containing a myriad of poorly staining fungal hyphae (Fig. 4). Granulomas were composed of a necrotic eosinophilic center surrounded by a rim of
degenerate hemocytes. Adjacent tissues were infilTable 1. Hemolymph analysis of an adult female captive cuttlefish with mycotic and bacterial dermatitis.
Hemocyte count
Total solids (refractometry)
Total protein
Glucose
Phosphorus
Calcium
Bilirubin (total)
Alkaline phosphatase
Aspartate aminotransferase
Potassium
Bicarbonate
0.50 ⫻ 103/␮l (0.5 ⫻ 109/L)
8.3 g/dl (83 g/L)
6.3 mg/dl (63 g/L)
2 mg/dl (0.1 mmol/L)
0.8 mg/dl (0.3 mmol/L)
31.3 mg/dl (7.8 mmol/L)
0.1 mg/dl (1.7 ␮mol/L)
1 IU/L
30 IU/L
9.4 mmol/L
6 mmol/L
trated with hemocytes admixed with proliferative,
swirling spindle cells. A Gomori methenamine silver (GMS) stain revealed abundant long, thin hyphae, 3–5 ␮m wide with roughly parallel walls, regularly spaced septate, infrequent branching, and occasionally segmental bulbous distensions.
Histologic findings suggested that the fungal infection was the main problem, with local bacterial
infection associated with the later ulceration. Based
on observations during surgery, it was thought that
excision had a reasonable chance of being curative,
although the multifocal distribution caused concern
about possible systemic distribution. Therefore, itraconazole (Sporonox, Janssen Pharmaceutica
Products, Titusville, New Jersey 08560, USA)
treatment was initiated at 5 mg/kg p.o. once daily
for 14 days (4–5 granules from a capsule, hidden
in food items), with good compliance.
Following surgery, the cuttlefish rapidly returned
to normal feeding and activity. Skin color changes
were limited to flashing a single eyespot instead of
two due to loss of one eyespot location with the
excised skin. No other areas of skin swelling developed, and most of the sutures were lost spontaneously, leaving healed incision lines. Two months
following surgery the cuttlefish reduced feeding for
a few days then was found dead. The whole animal
was preserved in 10% neutral buffered formalin.
Histopathology revealed severe multiorgan mycotic
infection similar to that described for the skin and
mantle biopsy.
528
JOURNAL OF ZOO AND WILDLIFE MEDICINE
Figure 4. Histopathology of biopsy site, H&E (a and b) and GMS (c and d) stains, ⫻10 (a and c) and ⫻40 (b
and d) objectives. Granulomas consist of a necrotic eosinophilic center surrounded by a rim of degenerate hemocytes
(a). Adjacent tissue is infiltrated with hemocytes admixed with proliferative spindle cells. Fungal hyphae (arrow in b,
and highlighted by GMS stain in c and d) within granulomas are 3–5 ␮m wide, septate, and branch infrequently.
DISCUSSION
Cuttlefish skin lesions are typically at the leading
edge of the mantle, considered secondary to collision trauma with the tank walls following startle
responses during which the animal jets rapidly
backward.18 As a result, the cuttlebone often fractures or is exposed and can become infected. Minimizing loud noises and sudden movements and
providing visual barriers are recommended to reduce occurrence of these injuries. The skin lesions
reported here differed in location and progression
from those seen as a result of external mantle trauma, appearing instead to originate as a focal eruptive lesion.
Vibrio spp. infections have been reported previously in cephalopods.2,7,10,13,15,17 These reports include myocarditis in European cuttlefish associated
with V. alginolyticus, V. parahaemolyticus, or Vibrio sp. myocarditis; and reproductive organ infections in three species of cuttlefish associated with
V. alginolyticus, often with concurrent epidermal
ulceration; eye, mantle, and other infections in European cuttlefish associated with Vibrio spp. and
other gram-negative bacteria; necrotic exfoliative
dermatitis in long-finned squid (Loligo pealei) associated with V. anguillarum; and fatal penetrating
skin ulcers in young pygmy octopus (Octopus joubini) and reef octopus (O. briareus) in high density
culture, associated with V. alginolyticus, V. damsela (now called Photobacterium damsela), and V.
parahaemolyticus. In captive brief squids, Lolliguncula brevis, bacterial species composition and concentrations (including Vibrio spp.) were similar between normal and ulcerated mantle, and authors
concluded that bacterial infections of ulcerated
mantle were secondary to physical trauma or other
stressors.2 When described histologically, these
Vibrio-associated lesions variously include necrosis, edema, hemocyte infiltration, intralesional bacteria, occasional giant cell formation, or necrotizing
HARMS ET AL.—CUTTLEFISH SURGERY
granulomatous-like inflammation.10,13,15 Although
Vibrio spp. can incite granulomatous-like inflammation in cuttlefish, the abundant fungal hyphae
observed within granulomas and subsequent systemic spread of fungal elements in the current case
supports the V. vulnificus isolated at the time of
biopsies having secondary importance in the inflammatory response. The alpha hemolytic Streptococcus sp. isolated prior to presentation was from
a surface swab, not reisolated from subsequent deep
tissue sampling, and likely a secondary contaminant.
Reports of fungal infections in cephalopods are
rare. Fusarium sp. in chambered nautilus and
Cladosporium sp. in an unspecified octopus species
have been reported but not described in detail.17
Cladosporium species are demateacious (pigmented) fungi of the phylum Ascomycota, typically
found as saprophytes or plant pathogens, but occasionally occurring as opportunistic skin and systemic infections of humans, the most pathogenic
species of which have been transferred to the genus
Cladophialophora.5 Cladosporiosis has been reported in a species of marine tropical fish, the tomato clownfish (Amphiprion frenatus) with deep
dermal ulcers, and was thought secondary to immunosuppression from transport or confinement
stress.19 The inciting cause in the cuttlefish of this
report is unknown. No conspecifics housed in the
same tank were similarly affected.
The moderately long anesthesia event with surgical excision of dermal fungal granulomas was
well tolerated by this cuttlefish, with rapid recovery
and incision healing. The skin proved more mobile,
elastic and durable than expected, which facilitated
sharp surgical excision and skin closure. An unanticipated consequence of the skin excision was the
loss of one false eyespot, indicating loss of specific
nerve endings, chromatophores or both, which may
have limited this cuttlefish’s intraspecific signaling
repertoire or its ability to startle potential predators.
Necropsy and histopathology findings indicated
eventual treatment failure, suggesting that more aggressive excision or more prolonged antifungal
treatment would have been warranted. Safety and
efficacy of antifungal treatments have not been
evaluated in cephalopods. It is unknown whether
orally administered itraconazole is adequately absorbed or if long-term administration would be safe
in cuttlefish. A formulary of empirically derived
treatment protocols for bacterial and protozoal diseases of cephalopods,3 and a pharmacokinetic study
of enrofloxacin in European cuttlefish4 have been
published. In the latter study, enrofloxacin clearance was more rapid and volume of distribution
529
was smaller than expected compared with fish and
other vertebrates, indicating that extrapolation of
vertebrate treatment protocols to invertebrates is
uncertain.
Although attempted treatment ultimately failed in
this cuttlefish, female European cuttlefish typically
live only 12–14 months,8,18 so it was near the end
of its expected life span. Senescence may have contributed to recrudescence of the fungal infection.
Organism complexity, a suitably large but manageable size, visual appeal, popularity as exhibit animals and utility as laboratory animals would usually favor individual animal veterinary management
when indicated for a cuttlefish patient. An inherent
drawback of performing more involved medical
and surgical procedures on cephalopods, however,
is their brief life span. Anesthetic and procedures
might still be useful in certain cases, for example,
to allow completion of a reproductive cycle. Based
on the management of this case, it is concluded that
cuttlefish are amenable to extended out-of-water
procedures if provided with adequate water circulation over the ctenidia and moisture over the rest
of the body, mantle skin is highly mobile and sufficiently strong to hold suture under mild tension,
and noneverting suture patterns are suitable for cuttlefish skin closure.
Acknowledgments: We thank Joy Bolynn for
photos, Stacey Gore for clinical consultation, Hap
Fatzinger for animal care oversight, Donald Meuten
and Kevin Woolard for pathology consultation, Michael Dykstra for fungal consultation, Linda Dunn
for assistance with figures, and students of the
NCSU-CVM Invertebrate Medicine Selective.
LITERATURE CITED
1. Barnes, R.D. 1980. Invertebrate Zoology, 4th ed. W.
B. Saunders Co., Philadelphia, Pennsylvania. Pp. 434–
466.
2. Ford, L. A., S. K. Alexander, K. M. Cooper, and R.
T. Hanlon. 1986. Bacterial populations of normal and ulcerated mantle tissue of the squid, Lolliguncula brevis. J.
Invert. Pathol. 48: 13–26.
3. Forsythe, F., R. T. Hanlon, and P. G. Lee. 1990. A
formulary for treating cephalopod mollusk diseases. In:
Perkins, F. O., and T. C. Cheng (eds.), Pathology in Marine
Science. Academic Press, New York, New York. Pp. 51–
63.
4. Gore, S. R., C. A. Harms, B. Kukanich, J. Forsythe,
G. A. Lewbart, and M. G. Papich. 2005. Enrofloxacin
pharmacokinetics in the European cuttlefish, Sepia officinalis, after a single i.v. injection and bath administration.
J. Vet. Pharmacol. Ther. 28: 433–439.
5. Guarro, J., J. Gene, and A. M. Stchigel. 1999. Developments in fungal taxonomy. Clin. Microbiol. Rev. 12:
454–500.
530
JOURNAL OF ZOO AND WILDLIFE MEDICINE
6. Hanlon, R. T., and J. W. Forsythe. 1985. Advances
in the laboratory culture of octopuses for biomedical research. Lab. Anim. Sci. 35: 33–40.
7. Hanlon, R. T., J. W. Forsythe, and K. M. Cooper.
1984. Fatal penetrating skin ulcers in laboratory-reared
octopuses. J. Invert. Pathol. 44: 67–83.
8. Jermann, T. 2001. Captive breeding of Sepia officinalis at the Basel Zoo. Bull. Inst. Oceanogr. 20: 261–265.
9. Lewbart, G. A., and C. A. Harms. 1999. Building a
fish anesthesia delivery system. Exotic DVM 1(2): 25–28.
10. Leibovitz, L., T. R. Meyers, R. Elston, and P. Chanley. 1977. Necrolytic exfoliative dermatitis of captive
squid (Loligo pealei). J. Invert. Pathol. 30: 369–376.
11. Oestmann, D. J., J. M. Scimeca, J. Forsythe, R. T.
Hanlon, and P. Lee. 1997. Special considerations for keeping cephalopods in laboratory facilities. Contemp. Top. 9:
89–93.
12. Reimschuessel, R., and M. K. Stoskopf. 1990. Octopus automutilation syndrome. J. Invert. Pathol. 55: 394–
400.
13. Reimschuessel, R., M. K. Stoskopf, and R. O. Bennett. 1990. Myocarditis in the common cuttlefish (Sepia
officinalis). J. Comp. Pathol. 102: 291–297.
14. Ross, L. G., and B. Ross. 1999. Anaesthetic and
Sedative Techniques for Aquatic Animals, 2nd ed. Blackwell Science, Oxford, United Kingdom. Pp. 46–57.
15. Sangster, C. R., and R. M. Smolowitz. 2003. Description of Vibrio alginolyticus infection in cultured Sepia officinalis, Sepia apama, and Sepia pharaonis. Biol.
Bull. 205: 233–234.
16. Schmidt-Nielsen, K. 1990. Animal Physiology: Adaptation and Environment, 4th ed. Cambridge University
Press, Cambridge, United Kingdom. Pp. 299–352.
17. Scimeca, J. M. 2006. Cephalopods. In: Lewbart, G.
A. (ed.). Invertebrate Medicine. Blackwell, Oxford, United Kingdom. Pp. 79–89.
18. Sherrill, J., L. H. Spelman, C. L. Reidel, and R. J.
Montali. 2000. Common cuttlefish (Sepia officinalis) mortality at the National Zoological Park: implications for
clinical management. J. Zoo Wildl. Med. 31: 523–531.
19. Silphaduang, J., K. Hatai, S. Wada, and E. Noga.
2000. Cladosporiosis in a tomato clownfish (Amphiprion
frenatus). J. Zoo Wildl. Med. 31: 259–261.
20. Stoskopf, M. K., and B. S. Oppenheim. 1996. Anatomic features of Octopus bimaculoides and Octopus digueti. J. Zoo Wildl. Med. 27: 1–18.
Received for publication 5 May 2006